JP2665468B2 - Airbag inflation device and manufacturing method - Google Patents

Abstract

An airbag inflation apparatus comprises a container (15) containing a supply of inflation fluid. The container has a first outer surface (19) and an inner surface (26) which is threaded and defines a threaded opening extending into the container from the first outer surface. A plug (40) has an outer periphery (45) which is threaded. The plug is screwed into the threaded opening in the container. The outer periphery of the plug includes a second outer surface (51) adjacent the first outer surface of the container. The outer periphery of the plug and the inner surface of the container that defines the threaded opening comprise an interface (11) between the plug and the container. The interface extends to the periphery of the container between the first and second outer surfaces. A ring (30) overlies both the interface and portions of the first and second outer surfaces. The ring is secured to the first and second outer surfaces to block leakage of inflation fluid from the container through the interface.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an airbag inflation device used for inflating a vehicle occupant restraint such as an airbag and a method of manufacturing the same.

[0002]

2. Description of the Prior Art Known airbag inflation devices used to inflate vehicle occupant restraints, such as airbags, have a container for containing pressurized inflation fluid. A body of ignition material is placed in this container. An ignition (igniter) assembly is activated to ignite the ignition material body.

As the ignition material burns, it heats the inflation fluid in the container to increase the fluid pressure in the container.

[0004] Typically, the container forms a substantially cylindrical chamber. The chamber is filled with pressurized inflation fluid, which is introduced into the chamber through a passage. Once the chamber is filled with the desired pressure of inflation fluid, the passage is closed. The container has a rupture disk which is ruptured in response to a vehicle deceleration large enough to indicate a collision of the vehicle. When the rupture disk is ruptured, the disk forms an outlet (opening) through which inflation fluid flows from the container chamber to the airbag to cause the airbag to inflate.

[0005]

However, the prior art as described above cannot completely prevent the expansion fluid from leaking.

SUMMARY OF THE INVENTION An object of the present invention is to provide an airbag inflation device which has a relatively simple structure, is easy to assemble, and can completely prevent leakage of inflation fluid.

[0007]

To achieve the above object, the present invention has the following arrangement. That is, according to one aspect of the present invention, there is provided an airbag inflation device, which includes a container containing an inflation fluid supply. The container has a first outer surface and an inner surface, the inner surface being at least partially threaded and forming a threaded opening extending into the container from the first outer surface.

[0008] A plug is provided, the plug having an outer periphery with a thread at least in part. This plug is screwed into the threaded opening of the container. The outer periphery of the plug has a second outer surface adjacent the first outer surface of the container. The outer periphery of the plug and the inner surface of the container forming the opening form an interface between the plug and the container. The interface extends around the container between the first and second outer surfaces. Inflation fluid leakage prevention means is provided for preventing inflation fluid leakage from the container through the interface, the means comprising (i) a ring covering the interface and covering portions of the first and second outer surfaces; Mounting means for mounting on the first and second outer surfaces.

In accordance with another aspect of the present invention, there is provided a method of manufacturing an airbag inflation device. The method forms a container. The container has a first outer surface and an internally threaded opening extending into the container from the first outer surface.

[0010] The method also includes screwing a plug having an at least partially threaded outer periphery into the threaded opening of the container. The outer periphery of the plug has a second outer surface adjacent the first outer surface of the container. Screwing the plug into the internally threaded opening of the container forms an interface between the plug and the container. The interface extends around the container between the first and second outer surfaces.

Also, the method of the present invention locates a ring over the interface and a portion of the first and second outer surfaces, and attaches the ring to the first and second outer surfaces to permit leakage of inflation fluid from the container through the interface. Preventing.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An airbag inflation device 10 according to the present invention is schematically illustrated in FIG. This airbag inflation device is an airbag 12 in the preferred embodiment shown in the drawings.
An inflation fluid is supplied to inflate the inflatable vehicle occupant restraint. As shown in FIGS. 1 and 5, the inflation device 10 has a non-activated state, in which the airbag 12 is in a contracted state, that is, a folded state. This inflation device 10, as shown in FIG.
The airbag 12 is in an inflated (expanded) state in this state. The expansion device 10 is activated in response to a vehicle deceleration of at least a predetermined size indicating occurrence of a vehicle collision. At this time, the airbag 12 is inflated from the contracted state to the inflated state, and in this state, the airbag 12 restrains the movement of the vehicle occupant and prevents the occupant from hitting the parts of the vehicle.

The inflation device 10 includes a container or container member 15 and an actuator assembly 16.
This container member 15 forms a container having a chamber for holding the pressurized inflation fluid.

Preferably, the container member 15 is
Made from 61-T6 aluminum material.

The container member 15 and the actuator assembly 16 together form a sealed storage chamber 18 for storing an inflation fluid such as a gas for inflating the airbag 12. The actuator assembly 16 opens the containment chamber 18 to release inflation fluid from the containment chamber 18 upon occurrence of at least a predetermined amount of vehicle deceleration indicative of the occurrence of a vehicle collision.

The container member 15 has a cylindrical side wall portion 20,
It has a neck wall 22 and an end wall 24.

The side wall 20 is centered on the axis 61. The neck wall 22 of the container member 15 has an inner surface 26, a part of which is provided with a screw. The inner surface 26 forms an opening in the neck wall 22. The neck wall 22 of the container member 15 also has a first annular surface 17 (FIG. 5) and a second annular surface 19 (FIG. 5), the first annular surface Extending radially outwardly and across the inner surface 26, the second annular surface extends parallel to and spaced from the first annular surface 17 along an axis 61.

The inflation fluid in the chamber 18 is preferably
Consists of a combustible gas mixture. The gas mixture includes a primary gas and a combustible gas. The primary gas contains most of the gas that inflates the airbag 12, and the combustible gas heats the primary gas when ignited. This gas mixture is in a homogeneous gas state. The primary gas preferably includes an oxidizing gas that assists the combustion of the combustible gas and an inert gas that inflates the airbag 12. The primary gas includes air (air) or an air mixture and an inert gas. The inert gas can be nitrogen, argon or a mixture of nitrogen and argon.

[0019] Preferably, the primary gas is air and the oxidizing gas is oxygen in the air. The flammable gas can be hydrogen, methane or a mixture of hydrogen and methane. Preferably, the combustible gas is hydrogen. A typical component of the gas mixture is about 12% hydrogen and 88% air by volume. This gas mixture is about 2,500 ps
It is housed in the housing chamber 18 at the pressure i, but may be housed at a different pressure.

Referring to FIGS. 1-5, actuator assembly 16 includes a plug or plug member 40, which is preferably made from a 6061-T6 aluminum material. The plug member 40 has an axis 61
At the center. This side wall 4
At one end of 4 a circular closing wall 46 extends across the axis 61. A tubular lip 47 projects axially from the other end of the side wall 44. The side wall portion 44 and the closing wall portion 46 form a chamber in the plug member 40. The lip 47 of the plug member 40 has an annular inner surface 48 (FIG. 3) which defines a central passage through the lip 47, the passage being formed between the chamber of the plug member 40 and the outside of the plug member. To communicate.

A plurality of gas flow openings 50 (FIGS. 1, 3 and 5) extend radially through the side wall 44 of the plug member 40 and communicate with the chambers of the plug member 40.

The closing wall 46 of the plug member 40 includes a pre-formed central breakage 58 and an annular rim 60, both of which are centered about an axis 61. As best shown in FIG. 5, the rim portion 60 includes an outer surface 62 and an inner surface 6.
And 4. An annular V-shaped groove 65 surrounds the break 58. The break has an outer surface 66 and an inner surface 68. The groove 65 is formed by the surface of the closed wall portion 46 where the stress of the material is concentrated, and is formed so as to interconnect the fracture portion 58 with the rim portion 60. Accordingly, the connecting portion of the groove 65 forms a ring-shaped boundary, at which position the breaking portion 58 of the closing wall portion 46 breaks from the rim portion 60.

As best shown in FIGS. 3 and 4, the side wall portion 44 of the plug member 40 includes an annular, externally threaded surface 45, which is a closed wall portion 46.
To the lips 47. At the end of the threaded surface 45 furthest from the closing wall 46, an annular flange 49 projects radially away from the outer periphery of the side wall 44. Threaded surface 45 of side wall portion 44 of plug member 40
The inner surface 26 of the neck wall 22 of the container member 15 when the plug member 40 is screwed into the container member 15.
Into the threaded part. The flange portion 49 has an annular radially extending surface 51, which is
1 is aligned with the second annular surface 19 of the neck wall 22 of the container member 15 when fully screwed into the container member 15, as shown in FIGS.

When the plug member 40 and the container member 15 are assembled together, an interface (boundary surface) 11 is formed between the plug member 40 and the container member 15 by a contact surface between the plug member 40 and the container member 15. You. The abutment surface includes a threaded surface 45 of the plug member 40 and a threaded portion of the inner surface 26 of the container member 15. The interface 11, as shown at position 13 in FIG.
At the connection between the surface 51 and the second annular surface 19, it extends around the plug member 40 and the container member 15.

As best shown in FIG.
0 is the second annular surface 1 of the flange portion 49 of the plug member 40 and the second annular surface 1 of the neck wall portion 22 of the container member 15.
9 and is arranged in contact with it. This welding ring 30
Preferably, it is made from a 6061-T6 aluminum material. The welding ring 30 covers the interface 11 at the position 13, wherein the welding ring extends around the plug member 40 and the container member 15. The welding ring 30 also covers the annular end face 51 of the plug member 40 and the second annular face 19 of the container member 15. The welding ring 30 is friction welded to the annular end surface 51 and the second annular surface 19 to form a hermetic seal between the container member 15 and the plug member 40.

In order to friction-weld the welding ring 30 to the container member 15 and the plug member 40, the welding ring 3
Numeral 0 is disposed on a spindle (not shown), and is attached to this spindle using a collet (not shown). The spindle is rotated at a speed of about 6,000 RPM and moves along the axis 61 so as to move the flat annular surface of the welding ring 30 into engagement with the annular end surface 51 and the second annular surface 19. Is moved in one direction. Welding ring 30
The magnitude of the pressure with which the surface 31 is pressed against the surfaces 19 and 51 depends on the actual width of the surface 31 of the welding ring 30.

When the surface 31 of the welding ring 30 is engaged with the surfaces 19 and 51, the material of the surface 31, the material of the surface 19 and the surface 5
Material 1 heats up (heats up) to a plastic state. The heated material of surface 19 and the heated material of surface 51 flow into the material of surface 31 to form a weld band 55 with each other. At the same time that the welding band 55 is formed, a curly flash (a curled welding beam) 63
Are formed around the welding band 55 (see FIG. 5).

After the welding band 55 and the curly flash 63 have been formed, the spindle is moved away from the welding ring 30. The welding band 55 and the curly flash 63 are cooled to form a welding joint to which the welding ring 30, the container member 15, and the plug member 40 are attached together. This weld joint forms a continuous ring extending around the plug member 40,
Further, a hermetic seal is formed between the plug member 40 and the container member 15.

Referring to FIGS. 2 and 4, the plug member 40 has first and second internal passages 190, 192 which are substantially parallel to the axis 61. Penetrates. Second passage 192
Has a diameter concentric with the first passageway 190 but greater than the diameter of the first passageway. The second passage 192 communicates with the accommodation room 18. The first passage 190 communicates with the filling port 194 that opens radially outward and communicates with the outside of the plug member 40.

A ball check valve assembly 196 having a ball 195, as shown in FIG.
At the end of the second passage adjacent to the second passage 19
2 are arranged.

The ball check valve assembly 196
Has a blade member 175 disposed in a central region of the second passage 192. The blade member is pressure-fit into the second passage 192 and engages the inner peripheral surface 191 of the plug member 40 forming the second passage 192.

A welding joint is formed and the welding ring 3 is formed.
After the container member 15 and the plug member 40 are attached together, a source of pressurized inflation fluid (not shown) is
4 and pressurized inflation fluid is introduced into the first passage 190 through this fill port 194. The pressure of the pressurized inflation fluid in the first passage 190 causes the ball 195 of the ball check valve assembly 196 to move from a position adjacent to the first passage 190 to the right as viewed in FIG. The ball 195 continues to move rightward until it engages the blade member 175. This ball 195 is the first passage 19
As it moves away from a position adjacent to zero, pressurized inflation fluid in the first passageway 190 flows around the ball 195 through the second passageway 192 through the blade member 175 and into the chamber 18.

After the chamber 18 has been filled with pressurized inflation fluid, the source of pressurized inflation fluid is removed from the fill port 194. The pressure of the pressurized inflation fluid in chamber 18 returns ball 195 to the left as viewed in FIG. The ball has first and second passages 190,
Continue to move to the left until it closely engages the tapered circumference between 192.

The pressure of the inflation fluid in the chamber 18, and thus in the second passage 192, maintains the ball 195 in intimate engagement with the tapered circumference between the first and second passages 190,192. Is enough. Therefore, it is possible to prevent the pressurized inflation fluid in the chamber 18 from flowing backward from the filling port 194 through the first and second passages 190 and 192. Next, the filling port 194 is sealed by friction welding a closing member to the flat surface of the plug member 40 surrounding the filling port.

When the chamber 18 is filled with a mixture of gases, as described above, the pressure of the stored gas mixture is
Acts axially outwardly on the outer surface 66 of the break 58 of the closing wall 46. The surrounding air pressure is at the same time
Acts inward in the axial direction on the inner side surface 68. As a result, the break 58 will experience a gas pressure difference between the pressure of the contained gas mixture and the surrounding air pressure. Since the pressure of the contained gas mixture is higher than the surrounding air pressure, this gas pressure difference creates a pressure that pushes the breakage portion 58 outwardly in the axial direction.

The material of the closing wall 46 at the connection between the rupture portion 58 and the rim portion 60 is formed by the stress generated by the pressure acting outward in the axial direction when the pressure applied to the rupture portion reaches a predetermined height. Set to destroy by.

After the chamber 18 has been filled with the inflation fluid, the actuator housing 70 is placed in the plug member 40, in which case the actuator housing 70 is supported by the plug member 40. This actuator housing 7
Numeral 0 is a tubular member centered on the axis 61. As shown in FIGS. 1 and 5, the actuator housing 70 is tightly housed through an opening formed by the protruding lip 47 of the plug member 40.

The welded portion 71 has a lip 47 projecting from the plug member 40 and a flange 72 of the actuator housing 70.
Prevent gas leakage between.

The actuator housing 70 has a base 73 and a guide 74. The base 73 has a flange 72 and a cylindrical base compartment 7.
6 having a threaded inner surface 75. Guide part 74
Has an annular end surface 78 and a smooth cylindrical inner surface 79.
This annular end surface 78 forms a circular opening 80. An inner surface 79 of the cylinder is provided with a guide passage 82 extending axially from the base compartment 76 through the guide portion 74 to the opening 80.
Is formed. A suitable piece of tape 83 may have an annular end face 78.
To cover and seal the opening 80.

As further shown in FIG. 5, an ignition tube 90 is supported within the actuator housing 70. The ignition tube 90 has a cylindrical casing 92. The casing 92 has a threaded outer surface 94 and an annular front end surface 96 defining an opening at the front end of the ignition tube 90. A pair of conductive pins 98 extend into the casing 92. Casing 92 contains a pyrotechnic charge 100 disposed within a sealed enclosure 102. The ignition charge 100 is ignited when current flows through the ignition tube between the pins 98. The ignition charge 100 is preferably ZrKClO ₄ , but other known ignition charges can be used for the ignition tube 90. When the luminous fill 100 is ignited, the luminous fill produces a burn, which burns the enclosure 10
2 and the hermetic seal is opened to discharge through the opening in the front end face 96 of the ignition tube 90.

The casing 92 is screwed into the base compartment 76 of the actuator housing 70, where the opening in the front end face 96 faces the guide passage 82. The threaded surfaces 75, 94 are screwed together closely enough to prevent gas leakage between the threaded surfaces. Alternatively, a welding force or other seal may be applied to the ignition tube 9
0 may be provided for sealing and holding. Accordingly, the ignition tube 90 is supported by the actuator housing 70 at a predetermined position to move the combustion material from the ignition charge 100 in the direction along the axis 61 and into the guide passage.

Also, as shown in FIG. 5, the actuator assembly 16 further includes a movable container 104 in the form of a firing member. The movable container 104 has a cylindrical outer surface 110, an annular rear end surface 112, and a conical front end surface 114. In the preferred embodiment of the present invention shown in the drawings, the cylindrical outer surface 110 of the movable container 104 has 0.15 inches (about 3.8 mm).
Having a diameter of The conical front end surface 114 is the outer surface 110
To form a pointed tip 115 of the movable container 104 that extends away from the container.

The movable container 104 further has a cylindrical inner surface 116 and a circular inner surface 118. The inner surfaces 116, 118 are identical to the outer surface 110 and together form a compartment 120 within the movable container 104. The compartment 120 has a cylindrical shape and has an open end provided on an annular rear end surface 112 and a closed end provided on a circular inner surface 118.

An ignitable material 122 is contained within a compartment 120 of the movable container 104. The ignitable material 122 is preferably BKNO ₃ , but other materials can be used as well as the pyrotechnic charge. In the preferred embodiment of the invention shown in the drawings, the ignitable material 122 has a surface 124 that fills the compartment 120 and extends across the open end of the compartment 120. The ignitable material 122 (also the pyrotechnic charge 100) is preferably protected from ambient conditions such as moisture. Such protection is provided by a wax coating over the cover or open end surface 124 of the compartment 120, such as a cap or shell.

The above-mentioned cap and the like are not shown.

When the inflator 10 is in the non-activated state shown in FIGS. 1 and 5, the movable container 104 is located within the actuator housing 70. More specifically, the movable container 104 has a non-actuated position that is closely fitted concentrically within the guide passage 82 of the guide portion 74 of the actuator housing 70. When the movable container 104 is in its non-activated position, the cylindrical outer surface 110 is tightly received by the releasable close engagement with the cylindrical inner surface 79 of the guide portion 74. This close engagement is complemented by swaging or shear pins of a guide portion 74 of the actuator housing 70 or the like. Additionally, the face 124 of the ignitable material 122 is axially opposed to the opening in the front end face 96 of the ignition tube 90.

The actuator assembly 16 further includes
An electric circuit 150 is included. This electric circuit 150 is a power supply 15
2 and a normally open switch 154, this power source is preferably a vehicle battery and / or a capacitor. Switch 154 is preferably a vehicle deceleration sensor 156.
The deceleration sensor 156 detects at least a predetermined magnitude of vehicle deceleration indicating a vehicle collision, and closes the switch 154 in response to such vehicle deceleration. Such deceleration sensors are known in the art. Electrical circuit 150 extends through ignition tube 90 between pins 98 and activates ignition tube 90 when switch 154 is closed.

When the vehicle has experienced at least a predetermined amount of deceleration indicative of a collision, the deceleration sensor 156 detects such deceleration of the vehicle and closes the switch 154.

When switch 154 is closed, current flows through ignition tube 90 between pins 98. Next, the ignition tube 9
The pyrotechnic charge 100 within 0 is ignited to generate combustion products.
This combustion product destroys the enclosure 102 and discharges it from the ignition tube 90. The combustion products emitted from the ignition tube 90
5 into the space 160 (FIG. 5) in the guide passageway 82 between the and the movable container 104 and axially to the movable container 104 across the space 160. When the combustion products from the igniter tube 90 reach the movable container 104, they ignite the ignitable material 122 in the compartment 120 at the surface 124. The ignitable material 122 then produces a combustible that is expelled from the open end of the compartment 120 and directed into the space 160. Face 12
Any protective body on 4 is destroyed.

The pyrotechnic charge 100 and the ignitable material 122
When the fuel is burning, these combustibles are initially deposited in the space 16 between the ignition tube 90 and the movable container 104.
0. The gaseous components of the combustible in the space 160 increase the pressure as the pyrotechnic charge 100 and the ignitable material 122 burn. The ignition tube 90 is securely held in the base compartment 76 by a screw connection. However, the movable container 104 is removably retained within the guide passage 82 by close engagement.

When the increasing gas pressure in the space 160 reaches a predetermined level, the gas pressure force acting axially on the movable container 104 is large enough to overcome close engagement. Become.

This gas pressure then causes the movable container 104 to move out of the guide passage 82 at a high speed from its non-activated position toward the opening 80. The movable container 104 has a mass with a certain amount of potential energy when the container is propelled at high speed.
The potential energy of the movable container 104 is sufficient to allow the container 104 to break the tape 83 and move outwardly through the opening 80 toward the closed wall 46.

The potential energy of the movable container 104 is further determined by the fact that the container
Suffice to be able to pierce the portion 170 of FIG. 8 (FIG. 6) to form a first hole 184 through which the break 58 can pass. Most preferably, the potential energy of the movable container 104 is such that the container 104
Is sufficient to drill a first hole 184 in a circular shape, where the diameter of the hole is
Is substantially equal to the diameter of the outer surface 110.

The first hole 184 comprises a first orifice through which the gas mixture in the chamber 18 is discharged. The flow area of this first orifice has a predetermined value approximately equal to the cross-sectional area of the container 104, and in a preferred embodiment of the present invention is 0.018 cubic inches (0.46 cubic millimeters). The gas mixture is ignited and burned by the hot combustion products generated by the actuator assembly 16, passes through the first orifice 184, and flows outward through the plug member 40 to the gas flow opening 50. A diffuser 176 (FIG. 1) having a plurality of gas outlets 178 then directs gas from gas flow openings 50 to airbag 12. A weld 179 between the diffuser 176 and the plug member 40 prevents leakage of gas flowing through the diffuser 176.
Another weld 177 between the diffuser 176 and the container member 15 also prevents leakage of gas flowing through the diffuser 176.

The movable container 104 is closed by the closed wall portion 46.
After the first orifice 184 has been pierced through the breaking portion 58, the movable container 104 continues to move to the right as viewed in the drawing and enters the storage chamber 18. Thus, the movable container 104 may cause the ignitable material 122 to break through the torn portion 17 of the breach 58 when the ignitable material is burning.
Together with the gas mixture into the gas mixture in the storage chamber 18. Combustion generated by the ignitable material 122 includes heated hot particles and hot gases. These combustion products are stored in the container 10
As 4 moves through the gas mixture, it continues to be released from compartment 120 of container 104. Therefore,
These combustibles are dispersed throughout the containment chamber 18 in the gas mixture sufficiently to ignite the combustible gases of the gas mixture more quickly.

The container 104 preferably extends from the closed wall 46 near the bottom wall 24 of the container member 15 to the axis 61.
Is propelled through the accommodation room 18. Ignitable material 12
2 preferably continues to release the combustion products into the gas mixture until the container 104 reaches the far end of the storage chamber 18. If necessary, a screen (not shown) may be provided inside the storage chamber 18 adjacent to the bottom wall 24 of the container member 15. This screen is a movable container 104
And captures the container 104 at the far end of the storage chamber 18. This screen also
The torn portion 170 (FIG. 6) of the break 58 of the closed wall 46 carried by the container 104 is captured.

If the combustible gas burns during discharge from or within chamber 18, this will generate heat and gaseous matter that will increase the temperature and pressure of the gas mixture. For example, in one test apparatus including a pressure vessel having a chamber similar to chamber 18, the pressure of the gas mixture may be about 2,000.
From an initial containment pressure of 0 to 2,500 psi to about 4,500
Increased to high pressure of ~ 5,500 psi.

The gas mixture has already started to burn,
Flows outwardly through the first orifice 184 and the pressure builds up inside the receiving chamber 18, but the closing wall 46
The breaking portion 58 of the gasket continues to receive the gas pressure difference between the side surfaces 66 and 68. Accordingly, the gas pressure differential across the break 58 is increased by the increasing pressure inside the storage chamber 18. When this gas pressure difference reaches a predetermined height level, the pressure acting axially outward on the break 58 reaches a corresponding predetermined height level. Then, as described above, the destruction portion 58
The material of the closed wall portion 46, which includes a stress increasing means (increases the breaking stress) connecting the rim portion 60 with the rim portion 60, breaks under the stress caused by pressure.

When the material of the closed wall portion 46 is broken, the broken portion 58 is moved by the gas flowing outward from the storage chamber 18.
The plug member 40 moves axially outward from the closing wall 46 and
Released to get inside. Accordingly, as shown in FIG. 6, a second hole 186 is formed through the closed wall portion 46. The second hole 186 has a circular shape, and has a diameter corresponding to the circular shape and a diameter around the breaking portion 58.

The second hole 186 is composed of a second orifice, through which gas is passed through the first orifice.
Exit 8. Because the second orifice 186 is substantially larger than the first orifice 184, the outflow of gas through this second orifice 186 is substantially less than the flow rate of gas that previously flowed through the first orifice 184. Often. This flow rate is further increased by the increase in pressure made by the gas mixture when the second orifice 186 is formed. Accordingly, the gas mixture pressurized during the combustion of the combustible gas quickly flows out of the storage chamber 18 to inflate the airbag 12.

[0061]

According to the present invention, there is an advantage that an airbag inflation apparatus which can completely prevent the leakage of the inflation fluid, has a relatively simple structure and is easy to assemble, and a method of manufacturing the same are provided. .

Note that the present invention is not limited to the above-described embodiment.
Note that various modifications can be made.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an airbag inflation device constructed and assembled in accordance with the present invention.

FIG. 2 is an end view of a plug used in the expansion device of FIG. 1;

FIG. 3 is a sectional view taken along line 3-3 of FIG. 2;

FIG. 4 is a sectional view taken along line 4-4 of FIG. 2;

FIG. 5 is an enlarged view of a part of FIG. 1 showing the expansion device in a non-activated state.

FIG. 6 is a view similar to FIG. 5, showing the expansion device in an activated state;

[Explanation of symbols]

10: Inflator 12: Airbag 15: Container 16: Actuator Assembly 18: Storage Chamber 30: Weld Ring 40: Plug 46: Closed Wall 58: Destruction 70: Actuator Housing 80: Opening 90: Ignition Tube 100: Ignition Fill Object 122: Ignition material

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Ponget P. Wipas Lamonton, Elm Street, Rochester 48307, Michigan, USA 311 (72) Inventor Paul T. Saccon 48309, Rochester, Michigan, USA・ Hills, North Amberland 1555 (56) Reference: Japanese Utility Model Laid-Open No. 52-23443 (JP, U) Japanese Utility Model Application No. 5-75022 (JP, U) US Patent 3,966,226 (US, A)

Claims (11)

(57) [Claims] 1. A device for inflating an airbag, comprising: a container for containing an inflation fluid supply, the container having a first outer surface and an inner surface at least partially threaded and forming a threaded opening. A container having the threaded opening extending from the first outer surface into the container, and a plug having an outer periphery at least partially threaded and threaded into the threaded opening of the container. A plug extending radially outwardly of the threaded outer periphery of the plug and forming a second outer surface adjacent to the first outer surface of the container and a peripheral surface contacting the inner surface of the container; The peripheral surface of the plug and the inner surface of the container form an interface between the plug and the container, the interface being the first outer surface And a leakage prevention means for preventing the inflation fluid from leaking from the container through the interface, and extending to the periphery of the container between the container and the second outer surface. A) a continuous ring of uniform thickness having a flat annular surface covering the interface and covering portions of the first and second outer surfaces; and (b) connecting the ring to the first and second outer surfaces. Means for attaching to an airbag inflator. 2. The airbag inflator of claim 1 wherein said leak proof means comprises a continuous ring of material extending around said plug. 3. The airbag inflator of claim 1 wherein said container defines a chamber for holding pressurized inflation fluid, said container having an end on which said first outer surface is located. 4. The plug includes a closing wall disposed to block flow of inflation fluid from the chamber to the airbag, wherein the closing wall includes a preformed break. The airbag inflation device according to claim 1, wherein the airbag can flow an inflation fluid from the chamber to the airbag at the time of destruction. 5. The airbag inflation device of claim 1, wherein the plug comprises means for forming a passage, and wherein the pressurized inflation fluid flows through the passage to fill the container with pressurized inflation fluid. 6. The airbag inflator of claim 1, wherein said ring and said mounting means provide a hermetic seal between said container and said plug. 7. A device for inflating an airbag, the container containing an inflation fluid supply having a first outer surface and an inner surface at least partially threaded and forming a threaded opening. A container having the threaded opening extending from the first outer surface into the container, and a plug having an outer periphery at least partially threaded and threaded into the threaded opening of the container. A plug extending radially outwardly of the threaded outer periphery of the plug and forming a second outer surface adjacent to the first outer surface of the container and a peripheral surface contacting the inner surface of the container; The peripheral surface of the plug and the inner surface of the container form an interface between the plug and the container, the interface being the first outer surface And a leakage prevention means for preventing the inflation fluid from leaking from the container through the interface, and extending to the periphery of the container between the container and the second outer surface. A) a ring covering the interface and covering portions of the first and second outer surfaces; and (b) means for attaching the ring to the first and second outer surfaces, the ring extending around a periphery of the plug. Mounting means having a continuous ring of material, wherein the continuous ring of material extending around said plug is friction welded between said ring and said first and second outer surfaces. 8. An airbag inflation device according to claim 7, wherein said container defines a chamber for holding pressurized inflation fluid, said container having an end on which said first outer surface is located. 9. The plug includes a closed wall portion arranged to block flow of inflation fluid from the chamber to the airbag, the closed wall portion including a pre-formed break portion, The airbag inflation device according to claim 7, wherein when inflation occurs, the inflation fluid can flow from the chamber to the airbag. 10. The airbag inflation device of claim 7, wherein the plug includes means for forming a passage, and wherein the pressurized inflation fluid flows through the passage to fill the container with pressurized inflation fluid. 11. The airbag inflator of claim 7, wherein said ring and said mounting means provide a hermetic seal between said container and said plug.